﻿// Copyright (c) Chris Pulman. All rights reserved.
// Licensed under the MIT license. See LICENSE file in the project root for full license information.

using System.Net;
using System.Text;

namespace ModbusRx.Utility;

/// <summary>
///     Modbus utility methods.
/// </summary>
public static class ModbusUtility
{
    private static readonly ushort[] CrcTable =
    {
            0X0000, 0XC0C1, 0XC181, 0X0140, 0XC301, 0X03C0, 0X0280, 0XC241,
            0XC601, 0X06C0, 0X0780, 0XC741, 0X0500, 0XC5C1, 0XC481, 0X0440,
            0XCC01, 0X0CC0, 0X0D80, 0XCD41, 0X0F00, 0XCFC1, 0XCE81, 0X0E40,
            0X0A00, 0XCAC1, 0XCB81, 0X0B40, 0XC901, 0X09C0, 0X0880, 0XC841,
            0XD801, 0X18C0, 0X1980, 0XD941, 0X1B00, 0XDBC1, 0XDA81, 0X1A40,
            0X1E00, 0XDEC1, 0XDF81, 0X1F40, 0XDD01, 0X1DC0, 0X1C80, 0XDC41,
            0X1400, 0XD4C1, 0XD581, 0X1540, 0XD701, 0X17C0, 0X1680, 0XD641,
            0XD201, 0X12C0, 0X1380, 0XD341, 0X1100, 0XD1C1, 0XD081, 0X1040,
            0XF001, 0X30C0, 0X3180, 0XF141, 0X3300, 0XF3C1, 0XF281, 0X3240,
            0X3600, 0XF6C1, 0XF781, 0X3740, 0XF501, 0X35C0, 0X3480, 0XF441,
            0X3C00, 0XFCC1, 0XFD81, 0X3D40, 0XFF01, 0X3FC0, 0X3E80, 0XFE41,
            0XFA01, 0X3AC0, 0X3B80, 0XFB41, 0X3900, 0XF9C1, 0XF881, 0X3840,
            0X2800, 0XE8C1, 0XE981, 0X2940, 0XEB01, 0X2BC0, 0X2A80, 0XEA41,
            0XEE01, 0X2EC0, 0X2F80, 0XEF41, 0X2D00, 0XEDC1, 0XEC81, 0X2C40,
            0XE401, 0X24C0, 0X2580, 0XE541, 0X2700, 0XE7C1, 0XE681, 0X2640,
            0X2200, 0XE2C1, 0XE381, 0X2340, 0XE101, 0X21C0, 0X2080, 0XE041,
            0XA001, 0X60C0, 0X6180, 0XA141, 0X6300, 0XA3C1, 0XA281, 0X6240,
            0X6600, 0XA6C1, 0XA781, 0X6740, 0XA501, 0X65C0, 0X6480, 0XA441,
            0X6C00, 0XACC1, 0XAD81, 0X6D40, 0XAF01, 0X6FC0, 0X6E80, 0XAE41,
            0XAA01, 0X6AC0, 0X6B80, 0XAB41, 0X6900, 0XA9C1, 0XA881, 0X6840,
            0X7800, 0XB8C1, 0XB981, 0X7940, 0XBB01, 0X7BC0, 0X7A80, 0XBA41,
            0XBE01, 0X7EC0, 0X7F80, 0XBF41, 0X7D00, 0XBDC1, 0XBC81, 0X7C40,
            0XB401, 0X74C0, 0X7580, 0XB541, 0X7700, 0XB7C1, 0XB681, 0X7640,
            0X7200, 0XB2C1, 0XB381, 0X7340, 0XB101, 0X71C0, 0X7080, 0XB041,
            0X5000, 0X90C1, 0X9181, 0X5140, 0X9301, 0X53C0, 0X5280, 0X9241,
            0X9601, 0X56C0, 0X5780, 0X9741, 0X5500, 0X95C1, 0X9481, 0X5440,
            0X9C01, 0X5CC0, 0X5D80, 0X9D41, 0X5F00, 0X9FC1, 0X9E81, 0X5E40,
            0X5A00, 0X9AC1, 0X9B81, 0X5B40, 0X9901, 0X59C0, 0X5880, 0X9841,
            0X8801, 0X48C0, 0X4980, 0X8941, 0X4B00, 0X8BC1, 0X8A81, 0X4A40,
            0X4E00, 0X8EC1, 0X8F81, 0X4F40, 0X8D01, 0X4DC0, 0X4C80, 0X8C41,
            0X4400, 0X84C1, 0X8581, 0X4540, 0X8701, 0X47C0, 0X4680, 0X8641,
            0X8201, 0X42C0, 0X4380, 0X8341, 0X4100, 0X81C1, 0X8081, 0X4040,
    };

    /// <summary>
    ///     Converts four UInt16 values into a IEEE 64 floating point format.
    /// </summary>
    /// <param name="b3">Highest-order ushort value.</param>
    /// <param name="b2">Second-to-highest-order ushort value.</param>
    /// <param name="b1">Second-to-lowest-order ushort value.</param>
    /// <param name="b0">Lowest-order ushort value.</param>
    /// <returns>IEEE 64 floating point value.</returns>
    public static double GetDouble(ushort b3, ushort b2, ushort b1, ushort b0)
    {
        var value = BitConverter.GetBytes(b0)
            .Concat(BitConverter.GetBytes(b1))
            .Concat(BitConverter.GetBytes(b2))
            .Concat(BitConverter.GetBytes(b3))
            .ToArray();

        return BitConverter.ToDouble(value, 0);
    }

    /// <summary>
    ///     Converts two UInt16 values into a IEEE 32 floating point format.
    /// </summary>
    /// <param name="highOrderValue">High order ushort value.</param>
    /// <param name="lowOrderValue">Low order ushort value.</param>
    /// <returns>IEEE 32 floating point value.</returns>
    public static float GetSingle(ushort highOrderValue, ushort lowOrderValue)
    {
        var value = BitConverter.GetBytes(lowOrderValue)
            .Concat(BitConverter.GetBytes(highOrderValue))
            .ToArray();

        return BitConverter.ToSingle(value, 0);
    }

    /// <summary>
    /// Converts two UInt16 values into a UInt32.
    /// </summary>
    /// <param name="highOrderValue">The high order value.</param>
    /// <param name="lowOrderValue">The low order value.</param>
    /// <returns>
    /// A unit.
    /// </returns>
    public static uint GetUInt32(ushort highOrderValue, ushort lowOrderValue)
    {
        var value = BitConverter.GetBytes(lowOrderValue)
            .Concat(BitConverter.GetBytes(highOrderValue))
            .ToArray();

        return BitConverter.ToUInt32(value, 0);
    }

    /// <summary>
    ///     Converts an array of bytes to an ASCII byte array.
    /// </summary>
    /// <param name="numbers">The byte array.</param>
    /// <returns>An array of ASCII byte values.</returns>
    public static byte[] GetAsciiBytes(params byte[] numbers) =>
        Encoding.UTF8.GetBytes(numbers.SelectMany(n => n.ToString("X2")).ToArray());

    /// <summary>
    ///     Converts an array of UInt16 to an ASCII byte array.
    /// </summary>
    /// <param name="numbers">The ushort array.</param>
    /// <returns>An array of ASCII byte values.</returns>
    public static byte[] GetAsciiBytes(params ushort[] numbers) =>
        Encoding.UTF8.GetBytes(numbers.SelectMany(n => n.ToString("X4")).ToArray());

    /// <summary>
    ///     Converts a network order byte array to an array of UInt16 values in host order.
    /// </summary>
    /// <param name="networkBytes">The network order byte array.</param>
    /// <returns>The host order ushort array.</returns>
    public static ushort[] NetworkBytesToHostUInt16(byte[] networkBytes)
    {
        if (networkBytes == null)
        {
            throw new ArgumentNullException(nameof(networkBytes));
        }

        if (networkBytes.Length % 2 != 0)
        {
            throw new FormatException(Resources.NetworkBytesNotEven);
        }

        var result = new ushort[networkBytes.Length / 2];

        for (var i = 0; i < result.Length; i++)
        {
            result[i] = (ushort)IPAddress.NetworkToHostOrder(BitConverter.ToInt16(networkBytes, i * 2));
        }

        return result;
    }

    /// <summary>
    ///     Converts a hex string to a byte array.
    /// </summary>
    /// <param name="hex">The hex string.</param>
    /// <returns>Array of bytes.</returns>
    public static byte[] HexToBytes(string hex)
    {
        if (hex == null)
        {
            throw new ArgumentNullException(nameof(hex));
        }

        if (hex.Length % 2 != 0)
        {
            throw new FormatException(Resources.HexCharacterCountNotEven);
        }

        var bytes = new byte[hex.Length / 2];

        for (var i = 0; i < bytes.Length; i++)
        {
            bytes[i] = Convert.ToByte(hex.Substring(i * 2, 2), 16);
        }

        return bytes;
    }

    /// <summary>
    ///     Calculate Longitudinal Redundancy Check.
    /// </summary>
    /// <param name="data">The data used in LRC.</param>
    /// <returns>LRC value.</returns>
    public static byte CalculateLrc(byte[] data)
    {
        if (data == null)
        {
            throw new ArgumentNullException(nameof(data));
        }

        byte lrc = 0;

        foreach (var b in data)
        {
            lrc += b;
        }

        lrc = (byte)((lrc ^ 0xFF) + 1);

        return lrc;
    }

    /// <summary>
    ///     Calculate Cyclical Redundancy Check.
    /// </summary>
    /// <param name="data">The data used in CRC.</param>
    /// <returns>CRC value.</returns>
    public static byte[] CalculateCrc(byte[] data)
    {
        if (data == null)
        {
            throw new ArgumentNullException(nameof(data));
        }

        var crc = ushort.MaxValue;

        foreach (var b in data)
        {
            var tableIndex = (byte)(crc ^ b);
            crc >>= 8;
            crc ^= CrcTable[tableIndex];
        }

        return BitConverter.GetBytes(crc);
    }
}
